Lecture 2
Cell Biology
Advanced Physiology of Animals
ANSC 3405
Chapters 3 to 4, Beginning 5
Outline
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Cell Structure and Organelles
Cell Molecular Components
Water and Chemical properties
Cell Membrane
Osmotic Properties of cells
Cell molecule transportation
Structure of
Animal Cells
Cell Video
Cell Organelles
• Nucleus
– 1 Nuclear envelope
– Chromatin and DNA
– Nucleolus
• Mitochondria
– Double membrane
– Mitochondrial (maternal) DNA
– “Power House” of the cell
• Food converted into energy
– Adenosine triphosphate (ATP)
• Consumes Oxygen, produces CO2
What is ATP?
• Nucleotides
– “Carry” chemical
energy from easily
hydrolyzed
phosphoanhydride
bonds
• Combine to form coenzymes (coenzyme A (CoA)
• Used as signaling molecules (cyclic AMP)
Cell Organelles
• Endoplasmic Reticulum
– Site where cell membrane and
exported material is made
– Ribosomes (rough)
• Make protiens
• Smooth ER- lipids
• Golgi Apparatus
– Recieves and modifies
– Directs new materials
• Lysosomes
– Intracellular digestion
– Releases nutrients
– Breakdown of waste
Cell Organelles
• Peroxisomes
– Hydrogen Peroxide generated and degraded
• Cytosol
– Water based gel
– Chemical reactions
• Cytoskeleton
– Filaments (actin, intermediate and microtubules)
– Movement of organelles and cell
– Structure/strengthen cell
• Vessicles
– Material transport
– Membrane, ER, Golgi derived vessicles
Organic molecules of Cells
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Proteins
Carbohydrates
Lipids
Nucleic acids
Proteins
• Most diverse and complex macromolecules
in the cell
• Used for structure, function and information
• Made of linearly arranged amino acid
residues
– “folded” up with “active” regions
Types of Proteins
1) Enzymes – catalyzes covalent bond breakage or
formation
2) Structural – collagen, elastin, keratin, etc.
3) Motility – actin, myosin, tubulin, etc.
4) Regulatory – bind to DNA to switch genes on or off
5) Storage – ovalbumin, casein, etc.
6) Hormonal – insulin, nerve growth factor (NGF), etc.
7) Receptors – hormone and neurotransmitter receptors
8) Transport – carries small molecules or irons
9) Special purpose proteins – green fluorescent protein, etc.
Lipids
• Hydrophobic molecules
– Energy storage, membrane components,
signal molecules
– Triglycerides (fat), phospholipids, waxes,
sterols
Carbohydrates
• Sugars, storage (glycogen, starch), Structural
polymers (cellulose and chitin)
• Major substrates of energy metabolism
Nucleic Acids
• DNA
(deoxyribonucleic
acid) and RNA
encode genetic
information for
synthesis of all
proteins
• Building blocks of
life
Water Molecule
• Polarity of H20 allows H bonding
• Water disassociates into H+ and
OH• Imbalance of H+ and OH- give
rise to “acids and bases”
- Measured by the pH
• pH influence charges of amino
acid groups on protein, causing a
specific activity
• Buffering systems maintain
intracelluar and extracellular pH
(Figure 3-6, pg 46)
Water Molecule
• Hydrophobic “Water-fearing”
– Molecule is not polar, cannot form H bonds
and is “repelled” from water
– Insoluble
• Hydrophillic “Water-loving”
– Molecule is polar, forms H bonds with water
– Soluble
Cell Membrane
Cell Membrane Composition
• Plasma membrane encloses cell and cell
organelles
• Made of hydrophobic and hydrophillic
components
– Semi-permeable and fluid-like
– “lipid bilayer”
Cell Membrane Composition
• Integral proteins interact with “lipid bilayer”
– Passive transport pores and channels
– Active transport pumps and carriers
– Membrane-linked enzymes, receptors and
transducers
• Sterols stabilize the lipid bilayer
– Cholesterol
(Figure 4-4, pg 81)
(Figure 4-2, pg 80)
Lipid Molecules
(Figure 4-3, pg 81)
Osmotic Properties of Cells
• Osmosis (Greek, osmos “to push”)
– Movement of water down its concentration
gradient
• Hydrostatic pressure
– Movement of water causes fluid mechanical
pressure
– Pressure gradient across a semi-permeable
membrane
Hydrostatic pressure
(Figure 4-9, pg 85)
Donnan Equilibrium
Add Ions
(Figure 4-9,
pg 81)
Deionized water
Semi-permeable
membrane
Balanced charges among
both sides
Donnan Equilibrium
Add anion
Diffusion
More Cl- leaves I to
balance charges
Ionic Steady State
• Potaasium cations
most abundant
inside the cell
• Chloride anions
ions most abundant
outside the cell
• Sodium cations
most abundant
outside the cell
Donnan equilibrium
[K+]i
[Cl-]ii
=
[K+]ii
[Cl-]i
A-
K+
Ca2+K+
A- Cl-K+
A- ANa+
Na+
Na+
Erythrocyte cell
equilibrium
•No osmotic pressure
- cell is in an isotonic solution
- Water does not cross
membrane
•Increased [Osmotic] in cytoplasm
- cell is in an hypotonic solution
- Water enters cell, swelling
•Decreased [Osmotic] in cytoplasm
- cell is in an hypotonic solution
- Water leaves cell, shrinking
(Figure 4-14, pg 90)
Cell Lysis
• Using hypotonic
solution
• Or interfering with
Na+ equilibrium
causes cells to burst
• This can be used to
researchers’
advantage when
isolating cells
(Figure 4-16, pg 91)
Molecules Related to Cell
Permeability
• Depends on
– Molecules size (electrolytes more
permeable)
– Polarity (hydrophillic)
– Charge (anion vs. cation)
– Water vs. lipid solubility
(Figures 4-18;19, pg 92)
Cell Permeability
• Passive transport is carrier mediated
– Facilitated diffusion
– Solute molecule combines with a “carrier” or
transporter
– Electrochemical gradients determines the
direction
– Integral membrane proteins form channels
Crossing the membrane
• Simple or passive diffusion
• Passive transport
– Channels or pores
• Facilitated transport
– Assisted by membrane-floating proteins
• Active transport pumps & carriers
– ATP is required
– Enzymes and reactions may be required
Modes of Transport
(Figure 4-17, pg 91)
Carrier-Mediated Transport
• Integral protein binds to the solute and undergo
a conformational change to transport the solute
across the membrane
(Figure 4-21, pg 93)
Channel Mediated Transport
• Proteins form aqueous pores allowing specific
solutes to pass across the membrane
• Allow much faster transport than carrier proteins
Coupled Transport
• Some solutes “go along for the ride” with a
carrier protien or an ionophore
Can also be a Channel
coupled transport
(Figure 4-22, pg 95)
Active transport
• Three main mechanisms:
– coupled carriers: a solute is
driven uphill compensated
by a different solute being
transported downhill
(secondary)
– ATP-driven pump: uphill
transport is powered by ATP
hydrolysis (primary)
– Light-driven pump: uphill
transport is powered by
energy from photons
(bacteriorhodopsin)
Active transport
• Energy is required
Na+/K+ Pump
• Actively transport Na+ out of the cell and K+ into the cell
•Against their
electrochemical
gradients
•For every 3 ATP, 3
Na+ out, 2 K+ in
(Figure 4-24, pg 96)
Na+/K+ Pump
• Na+ exchange
(symport) is
also used in
epithelial cells
in the gut to
drive the
absorption of
glucose from
the lumen, and
eventually into
the
bloodstream
(by passive
transport)
(Figure 4-35, pg 105)
(Figure 4-26, pg 97)
Na+/K+ Pump
• About 1/3 of ATP in an animal cell is used to
power sodium-potassium pumps
• In electrically active nerve
cells, which use Na+ and K+
gradients to propagate
electrical signals, up to 2/3 of
the ATP is used to power
these pumps
Endo and Exocytosis
• Exocytosis
- membrane vesicle fuses with cell
membrane, releases enclosed material to
extracellular space.
• Endocytosis
- cell membrane invaginates, pinches in,
creates vesicle enclosing contents
Receptor Mediated Endocytosis
(Figure 4-30, pg 102)
The End